JP6311443B2 - Measuring apparatus, measuring method and transmission system - Google Patents

Description

  The present invention relates to a measuring apparatus, a measuring method, and a transmission system.

  In wavelength division multiplexing communication, further improvement in communication speed is required as communication traffic increases. As a means for improving the communication speed, there is a method for improving the frequency utilization efficiency of the optical band. For example, with the Orthogonal Frequency Division Multiplexing (OFDM) technique and the Nyquist-WDM (Wavelength Division Multiplexing) technique, a plurality of channels can be arranged in a narrower frequency band than before, and the frequency utilization efficiency can be improved.

  Using such OFDM technology, Nyquist-WDM technology, etc., a transmission speed of 100 Gbps or more is realized by applying a super channel method in which optical signals of a plurality of subchannels are multiplexed and transmitted as one optical signal. Transmission systems are being considered.

JP 2012-175417 A JP 2013-201495 A

  By the way, the frequency of the optical signal changes depending on the characteristics of the light emitting element of the device that is the transmission source of the optical signal. For this reason, the center frequency of the optical signal of each subchannel transmitted from the transmission source device may deviate from the center frequency of each subchannel predetermined in the specification due to changes in the device environment, aging of the device, or the like. . However, even in that case, the frequency at which the intensity of the frequency spectrum of the optical signal locally peaks can be estimated as the center frequency of the subchannel, and the signal intensity of the subchannel can be measured. In addition, by detecting the frequency at which the intensity of the frequency spectrum of the optical signal becomes a trough as a boundary between subchannels, the center of the detected boundary is estimated as the center frequency of the subchannel, and the signal strength of the subchannel is measured. You can also.

  However, when multiple subchannels are arranged in a narrower frequency band than before in order to improve frequency utilization efficiency, the interval between the subchannels is also narrowed, so the valley of the intensity of the frequency spectrum of the optical signal between the subchannels Becomes narrower. Therefore, the resolution of the conventional power measurement device cannot detect the boundary between the subchannels, and cannot accurately measure the signal strength of the subchannels.

  In the Nyquist-WDM technique, the optical signal is converted into a Nyquist pulse, so that the outer shape of the frequency spectrum is rectangular. For this reason, the frequency at which the intensity of the frequency spectrum of the optical signal locally peaks is not necessarily close to the center frequency of the subchannel, and the center frequency of the subchannel cannot be estimated from the local peak. Therefore, when the Nyquist-WDM technology is used, the conventional power measurement device cannot measure the signal strength of the subchannel with high accuracy.

  For this reason, it is impossible to correctly determine whether or not an optical signal is output for each subchannel, and when the transmission quality of the entire super channel is poor, it is not possible to identify the subchannel in which an abnormality has occurred.

  The technology disclosed in the present application detects an abnormality in transmission power for each subchannel constituting the superchannel of wavelength division multiplex communication.

  In one aspect, the measuring device includes a specifying unit and a measuring unit. The specifying unit specifies a design value of the center frequency of the spectrum of the Nyquist pulsed optical signal for each subchannel constituting the superchannel of the wavelength division multiplexing communication. The measurement unit measures the power of the optical signal in a band narrower than the frequency band of the subchannel with the design value of the specified center frequency as the center for each subchannel.

  According to one embodiment, it is possible to detect an abnormality in transmission power for each subchannel constituting a superchannel of wavelength division multiplexing communication.

FIG. 1 is a diagram illustrating an example of a transmission system according to the first embodiment. FIG. 2 is an explanatory diagram showing an example of a frequency slot. FIG. 3 is an explanatory diagram showing an example of a super channel configuration. FIG. 4 is a diagram illustrating an example of the channel table. FIG. 5 is an explanatory diagram for explaining the influence of frequency fluctuation. FIG. 6 is a flowchart illustrating an example of the operation of the OCM according to the first embodiment. FIG. 7 is a diagram illustrating an example of a transmission system according to the second embodiment. FIG. 8 is a block diagram illustrating an example of a control device. FIG. 9 is a diagram illustrating an example of a device information table. FIG. 10 is an explanatory diagram illustrating an example of an attenuation adjustment process. FIG. 11 is a flowchart illustrating an example of the operation of the control device according to the second embodiment. FIG. 12 is a diagram illustrating an example of a computer that realizes the OCM function.

  Hereinafter, embodiments of a measuring device, a measuring method, and a transmission system disclosed in the present application will be described in detail with reference to the drawings. The following examples do not limit the disclosed technology. Each embodiment can be appropriately combined within a range in which processing contents are not contradictory.

[Configuration of Transmission System 1]
FIG. 1 is a diagram illustrating an example of a transmission system 1 according to the first embodiment. The transmission system 1 in this embodiment includes a transmission device 10 and an OCM (Optical Channel Monitor) 20. The transmission device 10 is connected to the optical communication network 2 via a transmission path 3 such as an optical fiber cable. The OCM 20 is connected to a coupler 4 provided on the transmission path 3 between the transmission device 10 and the optical communication network 2.

  The transmission apparatus 10 includes a plurality of transmitters 11-1 to 11 -n, a plurality of VOAs (Variable Optical Attenuation) 12-1 to n, and a multiplexer 13. Hereinafter, the transmitters 11-1 to n and the VOAs 12-1 to n are collectively referred to as the transmitter 11 and the VOA 12, respectively, without being distinguished from each other.

  Each transmitter 11 outputs a different optical signal according to transmission data. Each transmitter 11 shapes the optical signal into a Nyquist pulse with a roll-off rate α of 0.5 or less, for example, and outputs it to the VOA 12. Each VOA 12 adjusts the power attenuation of the optical signal output from the transmitter 11 to adjust the power of the optical signal output from the transmitter 11 to a predetermined power. The multiplexer 13 multiplexes the optical signals of the respective wavelengths, the power of which has been adjusted by the respective VOAs 12, and outputs the multiplexed optical signals to the optical communication network 2 via the transmission path 3.

Here, the channel configuration of the optical signal transmitted by the transmission apparatus 10 will be described. 2 is an explanatory diagram showing an example of a frequency slot defined in ITU-T G.694.1. In ITU-T G.694.1, each frequency slot is defined by a center frequency and a slot width. As shown in the following relational expression (1), the center frequency f ₀ of the frequency slot is assigned to a frequency that is n times 6.25 GHz (n is an integer) with 193.1 THz as a reference.

  The slot width W of the frequency slot is defined by m times 12.5 GHz (m is a natural number) as shown in the following relational expression (2).

  Any combination of frequency slots is allowed as long as the frequency slots do not overlap each other. Each frequency slot is represented by a combination of m and n as shown in FIG. 2, for example. For example, as shown in FIG. 2, the combination of m = 19 and n = 6 represents a frequency slot with a center frequency of 193.218875 THz and a bandwidth of 75 GHz.

FIG. 3 is an explanatory diagram showing an example of a super channel configuration. For example, a super channel as shown in FIG. 3 is set in each frequency slot. The super channel includes one or more subchannels # 1 to #n. In this embodiment, the center frequency of the super-channel f _0, f ₁ the center frequency of each sub-channel included in the super-channel, f _2, · · ·, defined as f _n. The center frequency f _1, f ₂ of each subchannel from the center frequency f ₀ of the super-channel, ..., an offset to f _n, respectively, Delta] f _1, Delta] f _2,..., A Delta] f _n defined To do.

  In this embodiment, the optical signal transmitted from the transmitter 10 is shaped into a Nyquist pulse with a roll-off rate α of 0.5 or less, for example. Therefore, the external shape of the frequency spectrum of each sub-channel included in the super channel is a substantially rectangular shape with a flat top as shown in FIG. 3, for example.

  Returning to FIG. The OCM 20 includes a BPF (Band Pass Filter) 21, a photodiode 22, an ADC (Analog to Digital Converter) 23, a spectrum analysis unit 24, a control unit 25, a reception unit 26, an output unit 27, and a holding unit 28. The OCM 20 is an example of a measurement device. The spectrum analysis unit 24 is an example of a measurement unit. The control unit 25 is an example of a specifying unit.

  The holding unit 28 holds the channel table 280. FIG. 4 is a diagram illustrating an example of the channel table 280. The channel table 280 stores the number of subchannels 282 included in the superchannel and the frequency offset value 283 of each subchannel in association with the channel type 281 that identifies the type of each superchannel.

For example, as shown in FIG. 4, a super channel with a channel type 281 of “400G-A” includes two subchannels. Further, for example, the offset value of the center frequency f ₁ of the subchannel with the channel number # 1 from the center frequency f ₀ of the super channel is −38 (GHz). Further, for example, the offset value of the center frequency f ₂ of the subchannel with the channel number # 2 from the center frequency f ₀ of the super channel is +38 (GHz). By referring to the channel table 280, the control unit 25 can quickly specify the design value of the center frequency of each subchannel.

  The BPF 21 is a wavelength tunable filter that passes an optical signal in a predetermined band with a specified frequency as a center. The BPF 21 receives the optical signal output from the transmission device 10 via the transmission path 3, and in the received optical signal, the optical signal having a predetermined bandwidth centered on the frequency specified by the control unit 25. Pass to diode 22. The passband bandwidth of the BPF 21 is narrower than the subchannel bandwidth. The bandwidth of the pass band of the BPF 21 is preferably, for example, 1/6 or more and 1/5 or less of the bandwidth of the subchannel. In the present embodiment, the bandwidth of the pass band of the BPF 21 is, for example, 6 GHz.

  The photodiode 22 receives the optical signal that has passed through the BPF 21 and outputs a voltage corresponding to the power of the received optical signal to the ADC 23. The ADC 23 converts the voltage output from the photodiode 22 into a digital value corresponding to the output voltage, and outputs the converted digital value to the spectrum analysis unit 24. The spectrum analysis unit 24 analyzes the frequency spectrum of the optical signal that has passed through the BPF 21 based on the digital value output from the ADC 23. Then, the spectrum analysis unit 24 calculates the power of the optical signal that has passed through the BPF 21, and sends information on the calculated power of the optical signal to the control unit 25.

  The receiving unit 26 receives the value of n that specifies the center frequency of the super channel and the channel type of the super channel from the user of the OCM 20. Then, the reception unit 26 sends the received n value and channel type to the control unit 25. The accepting unit 26 may accept the n value and the channel type from another device such as a general-purpose computer operated by the user via a communication line.

When the control unit 25 receives the n value and the channel type from the reception unit 26, the control unit 25 applies the received m value and n value to the above-described relational expression (1) to design the center frequency f ₀ of the super channel. Calculate the value.

Next, the control unit 25 refers to the channel table 280 in the holding unit 28 and specifies the number of channels associated with the received channel type. Then, the control unit 25 extracts offset values for the specified number of channels from the channel table 280. Then, the control unit 25 calculates design values of the center frequencies f _{1 to} f _n of the respective subchannels included in the super channel. Then, the control unit 25 sends the calculated design values of the center frequencies f _{1 to} f _n of the respective subchannels to the BPF 21 as designated frequencies.

  Next, the control unit 25 receives the measurement value of the power of the optical signal of each subchannel from the spectrum analysis unit 24. And the control part 25 determines the presence or absence of the subchannel which is outputting the electric power higher or lower than an allowable range based on the received measured value. The control unit 25 determines whether or not the power measured for each subchannel satisfies the following relational expression (3), for example.

  Here, P (i) indicates the power of the i-th subchannel calculated by the spectrum analysis unit 24. ΔPth (Low) is a lower limit value of the allowable range, and is −3 dB, for example. ΔPth (High) is the upper limit value of the allowable range, for example, +3 dB. Pave is an average value of power measured for all the subchannels included in the super channel, and is calculated using, for example, the following calculation formula (4).

  If there is a power that does not satisfy the relational expression (3) among the powers measured for each subchannel, the control unit 25 sends the identification information (for example, channel number) of the subchannel to the output unit 27. send.

  The output unit 27 outputs the sub-channel identification information received from the control unit 25 to an output device such as a display. Note that the output unit 27 may transmit the channel number received from the control unit 25 to another device via a communication line.

  Here, the frequency of the optical signal output from the transmitter 10 depends on the characteristics of the light emitting elements in the transmitter 11. For this reason, the center frequency of the subchannel may deviate from the design value due to the influence of temperature rise or aging. FIG. 5 is an explanatory diagram for explaining the influence of frequency fluctuation.

For example, as shown by reference numeral 50 in FIG. 5, even if the center frequency of the subchannel design is f _k , depending on the characteristics of the light emitting elements in the transmitter 11, for example, as indicated by reference numerals 51 and 52, In some cases, the center frequency of the subchannel may deviate from f _k to f _k ′ or f _k ″.

  Here, since the optical signal transmitted from the transmitter 10 is shaped into a Nyquist pulse with a roll-off rate α of 0.5 or less, for example, the external shape of the frequency spectrum of each subchannel is shown in FIG. As shown, the upper part has a substantially rectangular shape with a flat top. Therefore, if the pass band of the BPF 21 is within a flat range in the spectrum of the subchannel, the spectrum analysis unit 24 is almost the same as the vicinity of the center frequency of the subchannel even if the center frequency of the subchannel is slightly shifted. Measurement results can be obtained.

  In the present embodiment, the bandwidth of the pass band of the BPF 21 is narrower than the bandwidth of the subchannel. Further, the bandwidth of the pass band of the BPF 21 is preferably, for example, 1/6 or more and 1/5 or less of the bandwidth of the subchannel. As a result, even if the center frequency of the subchannel slightly deviates depending on the characteristics of the light emitting element, the spectrum analysis unit 24 can obtain a measurement result comparable to the vicinity of the center frequency of the subchannel.

  However, in the present embodiment, the bandwidth of the pass band of the BPF 21 is narrower (for example, 6 GHz) than the bandwidth of the subchannel (for example, 32 GHz). The BPF 21 does not scan the passband for one subchannel. For this reason, the power P (i) calculated for each subchannel by the spectrum analysis unit 24 is lower than the actually output power of the subchannel.

  However, since the control unit 25 measures the power under the same conditions for each subchannel included in the super channel, it is possible to obtain the relative relationship of the power between the subchannels. Therefore, the control unit 25 can detect an abnormal subchannel that outputs power higher or lower than the allowable range based on the power calculated for each subchannel by the spectrum analysis unit 24.

[Operation of OCM20]
FIG. 6 is a flowchart illustrating an example of the operation of the OCM 20 according to the first embodiment. For example, when the reception unit 26 receives an n value for specifying the center frequency of the super channel and the channel type of the super channel from the user of the OCM 20, the OCM 20 starts the operation illustrated in this flowchart.

First, the receiving unit 26 sends the received n value and channel type to the control unit 25 (S100). The control unit 25 applies the n value received from the control unit 25 to the relational expression (1) described above, and calculates the design value of the center frequency f ₀ of the super channel (S101).

  Next, the control unit 25 refers to the channel table 280 in the holding unit 28 and specifies the number of channels associated with the channel type received from the reception unit 26. And the control part 25 extracts the offset value for the specified number of channels from the channel table 280 (S102).

Next, the control unit 25 selects one unselected subchannel among the subchannels included in the super channel (S103). Then, the control unit 25 shifts the center frequency f ₀ of the super channel calculated in step S101 for the selected sub channel by a frequency corresponding to the offset value extracted in step S102, thereby design value of the center frequency of the sub channel. Is calculated (S104). Then, the control unit 25 sends the calculated design value of the center frequency of the subchannel to the BPF 21 as the designated frequency. The BPF 21 sets the frequency designated by the control unit 25 as the center frequency of the passband (S105).

  The photodiode 22 outputs a voltage according to the power of the optical signal that has passed through the BPF 21 to the ADC 23. The ADC 23 converts the voltage output from the photodiode 22 into a digital value, and outputs the converted digital value to the spectrum analysis unit 24. The spectrum analysis unit 24 analyzes the frequency spectrum of the optical signal that has passed through the BPF 21 based on the digital value output from the ADC 23, and measures the power of the optical signal that has passed through the BPF 21 (S106). Then, the spectrum analysis unit 24 sends the measured optical signal power to the control unit 25.

  Next, the control unit 25 determines whether or not all subchannels included in the super channel have been selected (S107). When there is an unselected subchannel (S107: No), the control unit 25 executes the process shown in step S103 again.

  On the other hand, when all the subchannels included in the super channel are selected (S107: Yes), the control unit 25 calculates the average power of the subchannel included in the superchannel using the above-described calculation formula (4). (S108).

  Next, the control unit 25 calculates a difference from the calculated average power for each subchannel. Then, the control unit 25 determines whether or not there is a subchannel whose difference from the average power is outside the allowable range, that is, whether or not there is a subchannel that does not satisfy the above-described relational expression (3) ( S109). When there is a subchannel that does not satisfy the relational expression (3) (S109: Yes), the control unit 25 sends identification information (for example, a channel number) of the subchannel that does not satisfy the relational expression (3) to the output unit 27. send. The output unit 27 outputs the sub-channel identification information received from the control unit 25 to an output device such as a display (S110), and the OCM 20 ends the operation shown in this flowchart.

  On the other hand, when the power of all the subchannels included in the super channel satisfies the relational expression (3) (S109: No), the OCM 20 ends the operation shown in this flowchart. When the power of all subchannels included in the super channel satisfies the relational expression (3) (S109: No), the control unit 25 sends information indicating no abnormality to the output unit 27, and the output unit 27 Information indicating no abnormality may be output to an output device such as a display.

[Effect of Example 1]
As described above, according to the OCM 20 of the present embodiment, it is possible to detect an abnormality in transmission power for each subchannel constituting the superchannel of wavelength division multiplexing communication.

[Configuration of Transmission System 1]
FIG. 7 is a diagram illustrating an example of the transmission system 1 according to the second embodiment. The transmission system 1 in this embodiment includes a transmission device 10, a plurality of OCMs 20, a reception device 30, and a control device 40. The receiving device 30 is connected to the optical communication network 2 via the transmission path 3 such as an optical fiber cable, and receives the optical signal transmitted from the transmitting device 10. Except for the points described below, in FIG. 7, the components denoted by the same reference numerals as those in FIG. 1 have the same or similar functions as those in FIG.

  The transmission apparatus 10 includes a plurality of transmitters 11-1 to 11 -n, a plurality of VOAs 12-1 to 12 -n, a multiplexer 13, and a control unit 14. Each VOA 12 controls the attenuation amount of the power of the optical signal output from the transmitter 11 according to the adjustment amount received from the control unit 14. When receiving the adjustment value of the attenuation amount for each subchannel from the control device 40, the control unit 14 sends the received adjustment value to the VOA 12 that controls the attenuation amount of each subchannel.

  Each OCM 20 includes a BPF 21, a photodiode 22, an ADC 23, a spectrum analysis unit 24, a control unit 25, a holding unit 28, and a communication unit 29. When the communication unit 29 receives n value and channel type information from the control device 40 via the communication line, the communication unit 29 sends the received n value and channel type information to the control unit 25. Further, when the communication unit 29 receives power information for each subchannel from the control unit 25, the communication unit 29 sends the received power information for each subchannel to the control device 40 via the communication line.

  The control device 40 receives power information for each subchannel from each OCM 20. Then, based on the received power information for each subchannel, control device 40 calculates an attenuation adjustment value for each subchannel setting. Then, the control device 40 transmits the calculated adjustment value for each subchannel to the transmission device 10 via the communication line.

[Configuration of Control Device 40]
FIG. 8 is a block diagram illustrating an example of the control device 40. The control device 40 includes an adjustment value calculation unit 41, a holding unit 42, a measurement instruction unit 43, and a reception unit 44.

  The holding unit 42 holds the device information table 420. FIG. 9 is a diagram illustrating an example of the device information table 420. For example, as illustrated in FIG. 9, device information 422, OCM_ID 423, and OCM information 424 are stored in the device information table 420 in association with a device ID 421 that identifies each transmitting device 10 or receiving device 30. The device information 422 is information regarding the transmission device 10 or the reception device 30 corresponding to the device ID 421. The device information 422 includes information used for communication with the transmission device 10 or the reception device 30 corresponding to the device ID 421, for example, an IP address or a MAC address.

  The OCM_ID 423 is information for identifying the OCM 20 that can measure an optical signal transmitted or received by the transmission device 10 or the reception device 30 corresponding to the device ID 421. The OCM information 424 is information related to the OCM 20 corresponding to the OCM_ID 423, and includes information used for communication with the OCM 20, such as an IP address and a MAC address.

  The accepting unit 44 accepts from the user of the control device 40 the value of n that identifies the center frequency of the super channel, the channel type of the super channel, the device ID of the transmitting device 10, and the device ID of the receiving device 30. Then, the reception unit 44 sends the received n value, channel type, device ID of the transmission device 10, and device ID of the reception device 30 to the adjustment value calculation unit 41 and the measurement instruction unit 43. The accepting unit 44 may accept the n value, the channel type, the device ID of the transmitting device 10, and the device ID of the receiving device 30 from another device such as a general-purpose computer operated by the user via the communication line. Good.

  When the measurement instruction unit 43 receives the n value, the channel type, the device ID of the transmission device 10 and the device ID of the reception device 30 from the reception unit 44, the measurement instruction unit 43 refers to the device information table 420 in the holding unit 42, OCM information corresponding to the received device ID is extracted. Then, the measurement instruction unit 43 transmits the n-value and channel type information received from the reception unit 44 to the OCM 20 corresponding to the extracted OCM information, respectively, via the communication line, so that the optical signal for each sub-channel is transmitted. The OCM 20 is instructed to perform the power measurement.

  When the adjustment value calculation unit 41 receives the n value, the channel type, the device ID of the transmission device 10, and the device ID of the reception device 30 from the reception unit 44, the adjustment value calculation unit 41 refers to the device information table 420 in the holding unit 42. Then, the adjustment value calculation unit 41 extracts the device information and the OCM information associated with the received device ID from the device information table 420, respectively. And the measurement instruction | indication part 43 hold | maintains the information of the received electric power as Padd (i), when the information of the electric power for every subchannel is received from OCM20 matched with apparatus ID of the transmitter 10. FIG. Here, Padd (i) indicates the power of the optical signal in the i-th subchannel transmitted by the transmission apparatus 10.

  When the power information for each subchannel is received from the OCM 20 associated with the device ID of the receiving device 30, the received power information is held as Pdrop (i). Here, Pdrop (i) indicates the power of the optical signal in the i-th subchannel received by the receiving device 30.

  Then, the adjustment value calculation unit 41 calculates an adjustment value of the attenuation amount of the optical signal for each subchannel transmitted from the transmission device 10 so that the power deviation of the optical signal between the subchannels is reduced in the reception device 30. To do. The adjustment value calculation unit 41 calculates an attenuation adjustment value ΔVOA (i) set for each subchannel in the transmission device 10 using the following calculation formula (5). The adjustment value ΔVOA (i) indicates an attenuation adjustment value set for the power of the optical signal in the i-th subchannel.

  Here, Loss (i) is calculated using, for example, the following calculation formula (6).

  In addition, AveLoss in the above calculation formula (5) is calculated using, for example, the following calculation formula (7).

  Then, the adjustment value calculation unit 41 transmits the calculated adjustment value ΔVOA (i) of the attenuation amount of the optical signal for each subchannel to the transmission device 10 via the communication line. The control unit 14 of the transmission apparatus 10 sends the received adjustment amount for each subchannel to the VOA 12 that adjusts the attenuation amount of the power of each subchannel. Each VOA 12 applies the received attenuation adjustment amount ΔVOA (i) to the current attenuation amount for the power of each subchannel i. As a result, the transmission power Padd (i, after) after adjustment of each subchannel i is expressed by the following relational expression (8).

  Here, the adjustment process of the attenuation amount of the transmission apparatus 10 will be described with reference to FIG. FIG. 10 is an explanatory diagram illustrating an example of an attenuation adjustment process. When the optical signal transmitted from the transmission device 10 passes through the optical communication network 2, it is attenuated by the loss of the optical fiber constituting the optical communication network 2, the stimulated Raman scattering effect, or the like. The amount of attenuation generally varies with wavelength. In addition, optical amplifiers and optical filters provided in the optical communication network 2 have wavelength dependence, and when an optical signal is relayed, a power deviation may occur for each wavelength.

  For example, as indicated by reference numeral 55 in FIG. 10, even when an optical signal with a small power deviation between subchannels is transmitted from the transmission device 10, when the optical signal reaches the reception device 30 through the optical communication network 2, for example, As indicated by reference numeral 56, the power deviation between the subchannels may increase. For example, in the power deviation indicated by reference numeral 56, the signal quality (for example, bit error rate) of the low-power subchannel may be deteriorated. In this case, the entire superchannel including a plurality of subchannels may be deteriorated. Signal quality will also deteriorate.

  Therefore, the control device 40 of this embodiment causes the OCM 20 provided at the transmission end of the transmission device 10 to measure the transmission power Padd (i) for each subchannel, and causes the OCM 20 provided at the reception end of the reception device 30 to The received power Pdrop (i) for each subchannel is measured. And the control apparatus 40 calculates the difference of transmission power Padd (i) and reception power Pdrop (i) as Loss (i) for every subchannel using the above-mentioned calculation formula (6). And the control apparatus 40 calculates the average value AveLoss of Loss (i) using the above-mentioned calculation formula (7).

  And the control apparatus 40 calculates the half of the difference of average value AveLoss and Loss (i) as adjustment value (DELTA) VOA (i) for every subchannel using the above-mentioned calculation formula (5). Then, the control device 40 instructs the transmission device 10 to apply the calculated adjustment value ΔVOA (i) to the current transmission power Padd (i) for each subchannel. As a result, the power of the optical signal in each subchannel transmitted from the transmission apparatus 10 is as indicated by reference numeral 57 in FIG. 10, for example.

  Thereby, the control apparatus 40 can make small the power deviation of the optical signal in each subchannel transmitted from the transmission apparatus 10, for example as shown to the code | symbol 58 of FIG. As a result, the occurrence of subchannels with extremely poor signal quality can be suppressed, and deterioration of signal quality of the entire super channel can be suppressed.

[Operation of Control Device 40]
FIG. 11 is a flowchart illustrating an example of the operation of the control device 40 according to the second embodiment. For example, when the reception unit 44 receives the n value of the super channel, the channel type of the super channel, the device ID of the transmission device 10, and the device ID of the reception device 30, from the user of the control device 40, the control device 40 starts the operation shown in this flowchart.

  First, the reception unit 44 sends the received n value, channel type, device ID of the transmission device 10, and device ID of the reception device 30 to the adjustment value calculation unit 41 and the measurement instruction unit 43. The measurement instruction unit 43 refers to the device information table 420 in the holding unit 42 and associates the OCM information corresponding to the device ID of the transmission device 10 received from the reception unit 44 with the device ID of the reception device 30 received. The extracted OCM information is extracted (S200). Then, the measurement instruction unit 43 transmits the n-value and channel type information received from the reception unit 44 to the OCM 20 corresponding to the extracted OCM information via the communication line (S201).

  Next, the adjustment value calculation unit 41 refers to the device information table 420 in the holding unit 42 and extracts device information and OCM information associated with the device ID received from the reception unit 44, respectively. Then, the measurement instruction unit 43 receives power information for each subchannel from each of the OCM 20 on the transmission device 10 side and the OCM 20 on the reception device 30 side (S202).

  Next, the adjustment value calculation unit 41 calculates the adjustment value of the attenuation amount for each subchannel using the above-described calculation formulas (5) to (7) (S203). Then, the adjustment value calculation unit 41 transmits the calculated adjustment value for each subchannel to the transmission device 10 via the communication line (S204), and the control device 40 ends the operation illustrated in this flowchart.

[Effect of Example 2]
As described above, according to the control device 40 of the present embodiment, the reception device 30 can suppress the deviation of the received power between the subchannels. Thereby, in the receiving device 30, the quality of the received signal can be improved.

[Modification]
Note that the technology disclosed in the present application is not limited to the above-described embodiments, and various modifications can be made within the scope of the gist thereof.

  In the first embodiment described above, the OCM 20 detects a subchannel in which power having a magnitude outside the allowable range is transmitted based on the power measured in a band narrower than the subchannel for each subchannel. However, the disclosed technology is not limited to this.

  For example, the control unit 25 of the OCM 20 calculates the power density per unit frequency based on the bandwidth of the pass band of the BPF 21 and the power calculated by the spectrum analysis unit 24 for each subchannel. Since the bandwidth of each subchannel is known, the control unit 25 may estimate the power of each subchannel by multiplying the calculated power density by the bandwidth of the subchannel. Then, the control unit 25 may determine, for each subchannel, whether the subchannel is transmitting abnormal power based on the calculated power of the entire subchannel. As a result, even if the number of subchannels that transmit normal power among the plurality of subchannels is smaller than the number of subchannels that transmit abnormal power, the abnormal power is reduced. The subchannel being transmitted can be detected.

In the first or second embodiment, the control unit 25 of the OCM 20 refers to the channel table 280 in the holding unit 28 and designs the center frequencies f _{1 to} f _n of the respective subchannels included in the super channel. Calculate the value. However, the disclosed technique is not limited to this, and the control unit 25 determines the center frequencies f _{1 to} f of the respective subchannels included in the super channel by a predetermined calculation based on the center frequency f ₀ and the channel type of the super channel. The design value of _n may be calculated. In this case, the holding unit 28 that holds the channel table 280 is not required in the OCM 20.

[HCM hardware configuration]
Note that the various processes described in the above embodiments can be realized by executing a program prepared in advance on a computer. Therefore, in the following, an example of a computer that executes a program having the same function as the above embodiment will be described. FIG. 12 is a diagram illustrating an example of a computer 70 that implements the functions of the OCM 20.

  In FIG. 12, a computer 70 that realizes the function of the OCM 20 includes a communication interface 71, an operation interface 72, a display interface 73, a ROM 74, a CPU 75, a RAM 76, and an HDD 77.

  For example, as shown in FIG. 12, a measurement processing program 770 is stored in the HDD 77 in advance. The CPU 75 reads the measurement processing program 770 from the HDD 77 and expands it in the RAM 76. The measurement processing program 770 may be appropriately integrated or separated as in the case of each component shown in FIG. 1 or FIG. Also, all the data stored in the HDD 77 does not always need to be stored in the HDD 77, and data necessary for processing may be stored in the HDD 77.

  The CPU 75 causes the measurement processing program 770 to function as the measurement processing process 760. The measurement process 760 develops various data read from the HDD 77 in an area allocated on the RAM 76 as appropriate, and executes various processes based on the developed data.

  In the OCM 20 in the first embodiment described above, the CPU 75 reads and executes the measurement processing program 770, whereby the BPF 21, the photodiode 22, the ADC 23, the spectrum analysis unit 24, the control unit 25, the reception unit 26, the output unit 27, and The same function as the holding unit 28 is exhibited.

  Further, in the OCM 20 in the above-described second embodiment, the CPU 75 reads and executes the measurement processing program 770, whereby the BPF 21, the photodiode 22, the ADC 23, the spectrum analysis unit 24, the control unit 25, the holding unit 28, and the communication unit. The same function as 29 is demonstrated.

  Note that the measurement processing process 760 in the first embodiment described above executes the processing executed in the OCM 20 shown in FIG. 1, for example, the processing shown in FIG. As for each processing unit virtually realized by the CPU 75, it is not always necessary for all the processing units to be realized by the CPU 75, and a processing unit necessary for processing may be realized virtually.

  Note that the measurement processing program 770 is not necessarily stored in the HDD 77 or the ROM 74 from the beginning. For example, each program is stored in a portable recording medium such as a flexible disk inserted into the computer 70, so-called FD, CD-ROM, DVD disk, magneto-optical disk, IC card or the like. Then, the computer 70 may acquire and execute each program from these portable recording media. Further, the computer 70 may acquire and execute each program from another computer or server device storing each program via a public line, the Internet, a LAN, a WAN, or the like.

DESCRIPTION OF SYMBOLS 1 Transmission system 2 Optical communication network 3 Transmission path 4 Coupler 10 Transmitter 11 Transmitter 12 VOA
13 multiplexer 14 control unit 20 OCM
21 BPF
22 Photodiode 23 ADC
24 spectrum analysis unit 25 control unit 26 reception unit 27 output unit 28 holding unit

Claims (6)

For each subchannel that constitutes a super channel in wavelength division multiplexing communication, a specifying unit that specifies the design value of the center frequency of the spectrum of the Nyquist pulsed optical signal,
A measurement apparatus comprising: a measurement unit that measures the power of an optical signal in a band narrower than the frequency band of the subchannel, with a design value of the specified center frequency as a center for each subchannel. And an output unit that outputs information of subchannels whose difference from the average power of the plurality of subchannels is outside a predetermined range based on the power of the optical signal measured for each subchannel by the measuring unit. The measuring apparatus according to claim 1. A holding unit that holds an offset value of the center frequency of each subchannel from the center frequency of the superchannel in association with the channel type that identifies the configuration of each superchannel;
And a reception unit for receiving a channel type designation,
The identifying unit extracts the offset value of the center frequency for each sub-channel from the holding unit for the super channel corresponding to the channel type received by the receiving unit, and corresponds to the extracted offset value from the center frequency of the super channel. 3. The measuring apparatus according to claim 1, wherein the frequency offset by the frequency to be specified is specified as a design value of a center frequency of a spectrum of a Nyquist pulsed optical signal.   The measurement unit measures, for each subchannel, the power of an optical signal in a band not less than 1/6 and not more than 1/5 of the frequency band of the subchannel, centered on the design value of the center frequency specified by the specifying unit. The measuring apparatus according to any one of claims 1 to 3, wherein Computer
Specify the design value of the center frequency of the Nyquist pulsed optical signal spectrum for each sub-channel that makes up the super channel,
A measurement method characterized in that, for each subchannel, processing for measuring the power of an optical signal in a band narrower than the frequency band of the subchannel is performed centering on a design value of the specified center frequency. A control device;
A first measurement device that measures the power of an optical signal transmitted from a communication device on the transmission side for each subchannel constituting a superchannel in wavelength division multiplexing communication;
A second measuring device that measures the power of the optical signal received by the receiving communication device for each subchannel;
Each of the first measuring device and the second measuring device is:
For each subchannel, a specifying unit that specifies a design value of the center frequency of the spectrum of the Nyquist pulsed optical signal;
A measurement unit that measures the power of an optical signal in a band narrower than the frequency band of the subchannel, with the design value of the specified center frequency being the center for each subchannel,
The controller is
A measurement instruction unit that instructs each of the first measurement device and the second measurement device to measure the power of the optical signal for each subchannel;
Based on the measurement result by the first measurement device and the measurement result by the second measurement device, the transmission-side communication device on the reception side reduces the electric deviation of the optical signal between the subchannels in the communication device on the reception side. An adjustment value calculating unit that calculates an adjustment value of the attenuation amount of the optical signal transmitted from the communication device for each subchannel, and transmits the calculated adjustment value to the communication device on the transmission side. system.

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